Optical microphone for eyewear devices

ABSTRACT

An audio system includes a transducer assembly, an optical sensing pathway, a laser, a detector assembly, and a controller. The transducer assembly is coupled to a user&#39;s ear and produces an acoustic pressure wave based on an audio instruction. The optical sensing pathway moves, at least in part, with a detected acoustic pressure wave. The laser emits light that is separated into a reference beam and a sensing beam that is coupled into the optical sensing pathway. The detected acoustic pressure wave interacts with the sensing beam to alter its optical path length. The detector assembly detects the reference and sensing beams from the optical sensing pathway, and measures the detected acoustic pressure wave based on changes in optical path length between the reference beam and the sensing beam. The controller adjusts the audio instruction based on the measurement of the detected acoustic pressure wave.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of co-pending U.S. application Ser.No. 16/192,441, filed Nov. 15, 2018, which is incorporated by referencein its entirety.

BACKGROUND

This disclosure relates generally to an audio system in an eyeweardevice, and specifically relates to an optical microphone for use ineyewear devices.

Head-mounted displays in an artificial reality system often includefeatures such as speakers or personal audio devices to provide audiocontent to users of the head-mounted displays. The audio systems inhead-mounted displays can include microphones positioned at or near theentrances of a user's ears to measure the sound produced by the speakersand calibrate the audio system. Current microphones for use inhead-mounted displays, such as binaural microphones or microphone arraysembedded in frames of head-mounted devices, have limited sensitivity.For example, typical microphones used in head-mounted devices havedifficulty detecting audio pressure waves produced by bone conductiontransducers, which generate particle displacements outside the ear inthe nanometer or picometer range. To generate pressure waves that can bedetected by existing microphones, bone conduction transducers mustproduce a very loud volume, which is unpleasant for the user.

SUMMARY

This present disclosure describes an audio system that includes anoptical microphone for detecting audio waves with a higher sensitivitythan previous microphones. The audio system may be a component of aneyewear device that is a component of an artificial reality head-mounteddisplay (HMD). The audio system includes at least one transducer thatproduces acoustic pressure waves, and an optical microphone to detectthe acoustic pressure waves. The optical microphone can be positioned atthe entrance to the user's ear canal or in the vicinity of the user'sear. The optical microphone includes a laser that emits light that isseparated into a sensing beam and a reference beam, e.g., using a beamsplitter. The sensing beam travels through an optical sensing pathway,such as an optical fiber. The acoustic wave interacts with the sensingbeam while it is in the optical sensing pathway by altering the opticalpath length of the sensing beam. A detector assembly receives thesensing beam from the optical sensing pathway, and also receives thereference beam. The detector measures the detected acoustic pressurewave based on the change in optical path length of the sensing beam. Theaudio system may adjust the acoustic pressure waves produced by thetransducer based on the measurement of the detected acoustic pressurewave.

In some embodiments, an audio system is described herein. The audiosystem includes a transducer assembly, an optical sensing pathway, alaser, a detector assembly, and a controller. The transducer assemblyconfigured to be coupled to an ear of a user and to produce an acousticpressure wave based on an audio instruction. The optical sensing pathwayis configured to move, at least in part, with a detected acousticpressure wave. The laser is configured to emit light that is separatedinto a reference beam and a sensing beam. The sensing beam is coupledinto the optical sensing pathway, and the detected acoustic pressurewave interacts with the sensing beam in the optical sensing pathway toalter an optical path length of the sensing beam. The detector assemblyis configured to detect the reference beam and detect the sensing beamfrom the optical sensing pathway, and measure the detected acousticpressure wave based in part on changes in optical path length betweenthe reference beam and the sensing beam. The controller is configured toadjust the audio instruction based on the measurement of the detectedacoustic pressure wave.

Embodiments according to the invention are in particular disclosed inthe attached claims directed to an audio system and an eyewear device,wherein any feature mentioned in one claim category, e.g. audio system,can be claimed in another claim category, e.g. eyewear device, system,method, storage medium, or computer program product, as well. Thedependencies or references back in the attached claims are chosen forformal reasons only. However any subject matter resulting from adeliberate reference back to any previous claims (in particular multipledependencies) can be claimed as well, so that any combination of claimsand the features thereof is disclosed and can be claimed regardless ofthe dependencies chosen in the attached claims. The subject-matter whichcan be claimed comprises not only the combinations of features as setout in the attached claims but also any other combination of features inthe claims, wherein each feature mentioned in the claims can be combinedwith any other feature or combination of other features in the claims.Furthermore, any of the embodiments and features described or depictedherein can be claimed in a separate claim and/or in any combination withany embodiment or feature described or depicted herein or with any ofthe features of the attached claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of an eyewear device including an audiosystem, in accordance with one or more embodiments.

FIG. 2A is a profile view a portion of an audio system including anoptical fiber microphone as a component of an eyewear device, inaccordance with one or more embodiments.

FIG. 2B is a profile view a portion of an audio system including anoptical microphone with a flexible membrane as a component of an eyeweardevice, in accordance with one or more embodiments.

FIG. 3 is a block diagram of an audio system, in accordance with one ormore embodiments.

FIG. 4 is a block diagram of a microphone assembly of the audio system,in accordance with one or more embodiments.

FIG. 5 is a system environment of an eyewear device including an audiosystem, in accordance with one or more embodiments.

The figures depict embodiments of the present disclosure for purposes ofillustration only. One skilled in the art will readily recognize fromthe following description that alternative embodiments of the structuresand methods illustrated herein may be employed without departing fromthe principles, or benefits touted, of the disclosure described herein.

DETAILED DESCRIPTION

Embodiments of the invention may include or be implemented inconjunction with an artificial reality system. Artificial reality is aform of reality that has been adjusted in some manner beforepresentation to a user, which may include, e.g., a virtual reality, anaugmented reality, a mixed reality, a hybrid reality, or somecombination and/or derivatives thereof. Artificial reality content mayinclude completely generated content or generated content combined withcaptured (e.g., real-world) content. The artificial reality content mayinclude video, audio, haptic sensation, or some combination thereof, andany of which may be presented in a single channel or in multiplechannels (such as stereo video that produces a three-dimensional effectto the viewer). Additionally, in some embodiments, artificial realitymay also be associated with applications, products, accessories,services, or some combination thereof, that are used to, e.g., createcontent in an artificial reality and/or are otherwise used in (e.g.,perform activities in) an artificial reality. The artificial realitysystem that provides the artificial reality content may be implementedon various platforms, including an eyewear device, a head-mounteddisplay (HMD) assembly with the eyewear device as a component, a HMDconnected to a host computer system, a standalone HMD, a mobile deviceor computing system, or any other hardware platform capable of providingartificial reality content to one or more viewers.

System Architecture

An audio system includes an optical microphone for measuring soundprovided to an ear of a user. The audio system comprises one or moretransducers, such as cartilage conduction transducers, air conductiontransducers, or bone conduction transducers. The transducers produceacoustic pressure waves sensed by a user's ear. Because ear shape andconfiguration varies between users, transducers produce acousticpressure waves that vary from user to user. The acoustic pressure wavesmay be airborne pressure waves or tissue borne pressure waves (e.g., anacoustic pressure wave that propagates through bone, cartilage, or oneor more other tissues), depending on the transducer used. For example, acartilage conduction transducer vibrates an auricle of the user's ear,which creates an airborne acoustic pressure wave at an entrance of theear that travels down an ear canal to an eardrum where it is perceivedas sound by the user. In response to a given vibration of a cartilageconduction transducer, different ear geometries produce differentairborne acoustic pressure waves. The optical microphone measures theacoustic pressure waves generated by the transducers, and provides themeasurement to a controller that adjusts audio instructions to thetransducers according to the measurement.

The optical microphone disclosed herein includes an optical sensingpathway that moves with a detected acoustic pressure wave. The movementof the optical sensing pathway alters an optical path length of asensing beam that travels through the optical sensing pathway. Measuringthe change in optical path length provides a measurement of the detectedacoustic pressure wave. The optical microphone configuration describedherein is highly sensitive. For example, the optical microphone candetect particle deflections in the nanometer or picometer range, whichenables measurement of airborne pressure waves generated by a boneconduction transducer at the outside of a user's ear, even at a lowvolumes. Thus, the optical microphone can be used to calibrate the audioinstructions to the transducers without the need for unpleasant,high-volume sounds.

FIG. 1 is a perspective view of an eyewear device 100 including an audiosystem, in accordance with one or more embodiments. The eyewear device100 presents media to a user. In one embodiment, the eyewear device 100may be a component of a head-mounted display (HMD). In some embodiments,the eyewear device 100 is a near-eye display. Examples of mediapresented by the eyewear device 100 include one or more images, video,audio, or some combination thereof. The eyewear device 100 may include,among other components, a frame 105, a lens 110, a sensor device 115, atransducer assembly 120, an optical microphone assembly 125, and acontroller 150.

The eyewear device 100 may correct or enhance the vision of a user,protect the eye of a user, or provide images to a user. The eyeweardevice 100 may be eyeglasses which correct for defects in a user'seyesight. The eyewear device 100 may be sunglasses which protect auser's eye from the sun. The eyewear device 100 may be safety glasseswhich protect a user's eye from impact. The eyewear device 100 may be anight vision device or infrared goggles to enhance a user's vision atnight. The eyewear device 100 may be a HMD that produces artificialreality content for the user. Alternatively, the eyewear device 100 maynot include a lens 110 and may be a frame 105 with an audio system thatprovides audio (e.g., music, radio, podcasts) to a user.

The frame 105 includes a front part that holds the lens 110 and endpieces to attach to the user. The front part of the frame 105 bridgesthe top of a nose of the user. The end pieces (e.g., temples) areportions of the frame 105 to which the temples of a user are attached.The length of the end piece may be adjustable (e.g., adjustable templelength) to fit different users. The end piece may also include a portionthat curls behind the ear of the user (e.g., temple tip, ear piece).

The lens 110 provides or transmits light to a user wearing the eyeweardevice 100. The lens 110 is held by a front part of the frame 105 of theeyewear device 100. The lens 110 may be prescription lens (e.g., singlevision, bifocal and trifocal, or progressive) to help correct fordefects in a user's eyesight. The prescription lens transmits ambientlight to the user wearing the eyewear device 100. The transmittedambient light may be altered by the prescription lens to correct fordefects in the user's eyesight. The lens 110 may be a polarized lens ora tinted lens to protect the user's eyes from the sun. The lens 110 maybe one or more waveguides as part of a waveguide display in which imagelight is coupled through an end or edge of the waveguide to the eye ofthe user. The lens 110 may include an electronic display for providingimage light and may also include an optics block for magnifying imagelight from the electronic display. Additional detail regarding the lens110 can be found in the detailed description of FIG. 5.

The sensor device 115 estimates a current position of the eyewear device100 relative to an initial position of the eyewear device 100. Thesensor device 115 may be located on a portion of the frame 105 of theeyewear device 100. In other embodiments, the sensor device 115 may belocated in a different location from the location shown in FIG. 1. Thesensor device 115 includes a position sensor and an inertial measurementunit. Additional details about the sensor device 115 can be found in thedetailed description of FIG. 5.

The audio system of the eyewear device 100 comprises a transducerassembly 120 configured to provide audio content to a user of theeyewear device 100 and an optical microphone assembly 125 configured todetect acoustic pressure waves produced by the transducer assembly 120.In the illustrated embodiment of FIG. 1, the audio system of the eyeweardevice 100 includes the transducer assembly 120, the optical microphoneassembly 125, and the controller 130. The audio system provides audiocontent to a user by utilizing the transducer assembly 120. The audiosystem also uses feedback from the optical microphone assembly 125 tocreate a similar audio experience across different users. The controller130 manages operation of the transducer assembly 120 by generating audioinstructions. The controller 130 also receives feedback as monitored bythe microphone assembly 120, e.g., for updating the audio instructions.Additional detail regarding the audio system can be found in thedetailed description of FIG. 3.

Various types of transducers are available for outputting audio contentto a user's ear. The transducer assembly 120 can include a single typeof transducer, such as a cartilage conduction transducer, a boneconduction transducer, or an air conduction transducer. Alternatively,the transducer assembly 120 is a hybrid transducer that includes two ormore types of transducers. For example, the transducer assembly 120includes two transducers configured to vibrate over two differentfrequency ranges, which may or may not overlap. The transducer assembly120 operates according to audio instructions, which may include acontent signal, a control signal, and a gain signal. The content signalmay be based on audio content for presentation to the user. The controlsignal may be used to enable or disable the transducer assembly 120 orone or more transducers of the transducer assembly. The gain signal maybe used to adjust an amplitude of the content signal.

In some embodiments, the transducer assembly 120 includes a cartilageconduction transducer that produces sound by vibrating cartilage in theear of the user. In an embodiment, a cartilage conduction transducer iscoupled to an end piece of the frame 105 and is configured to be coupledto the back of an auricle of the ear of the user. The auricle is aportion of the outer ear that projects out of a head of the user. Thecartilage conduction transducer receives audio instructions from thecontroller 130 and vibrates the auricle to generate an airborne acousticpressure wave at an entrance of the user's ear according to the audioinstructions.

In some embodiments, the transducer assembly 120 includes an airconduction transducer that produces sound by generating an airborneacoustic pressure wave in the ear of the user. In an embodiment, the airconduction transducer is coupled to an end piece of the frame 105 and isplaced in front of an entrance to the ear of the user. The airconduction transducer receives audio instructions from the controller130.

In some embodiments, the transducer assembly 120 includes a boneconduction transducer that produces sound by vibrating bone in theuser's head. In an embodiment, the bone conduction transducer is coupledto an end piece of the frame 105 and is configured to be behind theauricle and coupled to a portion of the user's bone. The bone conductiontransducer receives audio instructions from the controller 130 andvibrates the portion of the user's bone according to the audioinstructions. The bone vibration generates a tissue borne acousticpressure wave that propagates toward the user's cochlea, therebybypassing the eardrum.

The optical microphone assembly 125 detects an acoustic pressure wave atthe entrance of the ear of the user. The optical microphone assembly 125is coupled to an end piece of the frame 105. The optical microphoneassembly 125, as shown in FIG. 1, includes an optical sensing pathway,such as an optical fiber, that is positioned at the entrance of theuser's ear. The optical microphone assembly 125 also includes a laserand a detector assembly, which are coupled to or housed in the frame105. For example, the laser and/or detector assembly may be housed inthe frame 105 at or near the controller 130, or housed in the end pieceof the frame 105 to which the optical sensing pathway is coupled. Thelaser is configured to emit light into the optical sensing pathway, andthe detector assembly is configured to detect light that has traveledthrough the optical sensing pathway. The detector measures the acousticpressure wave in the vicinity of the user's ear based on an optical pathlength of the detected light.

In the embodiment shown in FIG. 1, the optical fiber is configured sothat the optical microphone assembly 125 directly measures an acousticpressure wave at the entrance of the ear of the user. In otherembodiments, the optical fiber is located in a different location in thevicinity of the user's ear. In still other embodiments, the opticalmicrophone assembly 125 includes an optical fiber coupled to a flexiblemembrane that is configured to be coupled to the back of the auricle ofthe user, and the optical microphone assembly 125 indirectly measuresthe acoustic pressure wave at the entrance of the ear. For example, theoptical microphone assembly 125 may measure a vibration that is areflection of the acoustic pressure wave at the entrance of the earand/or measure a vibration created by the transducer assembly 120 on theauricle of the ear of the user, which may be used to estimate theacoustic pressure wave at the entrance of the ear. In other embodiments,the flexible membrane with the optical fiber is coupled to a bone in theuser's head or other tissue. Additional detail regarding the opticalmicrophone assembly 125 can be found in the detailed description of FIG.3.

The controller 130 provides audio instructions to the transducerassembly 120 and receives information from the optical microphoneassembly 125 regarding the produced sound, and updates the audioinstructions based on the received information. The audio instructionsmay be generated by the controller 130. The controller 130 may receiveaudio content (e.g., music, calibration signal) from a console forpresentation to a user and generate audio instructions based on thereceived audio content. Audio instructions instruct the transducerassembly 120 or each transducer of the transducer assembly 120 how toproduce vibrations. For example, audio instructions may include acontent signal (e.g., a target waveform based on the audio content to beprovided), a control signal (e.g., to enable or disable the transducerassembly), and a gain signal (e.g., to scale the content signal byincreasing or decreasing an amplitude of the target waveform). Ifmultiple transducers are included in the transducer assembly 120, thecontroller 130 tailors different audio instructions for differenttransducers. For example, an acoustic pressure wave generated by a boneconduction transducer generally has a smaller magnitude than theacoustic pressure waves generated by cartilage or air conductiontransducers. In addition, the frequency responses of differenttransducers may be different, so the controller 130 adjusts theinstructions for each transducer based on their frequency responses.

The controller 130 also receives information from the optical microphoneassembly 125 that describes the produced sound at an ear of the user.The controller 130 uses the received information as feedback to compareto the produced sound to a target sound (e.g., audio content) andupdates the audio instructions to make the produced sound closer to thetarget sound. For example, the controller 130 updates audio instructionsfor a cartilage conduction transducer assembly to adjust vibration ofthe auricle of the user's ear to come closer to the target sound. Thecontroller 130 is embedded into the frame 105 of the eyewear device 100.In other embodiments, the controller 130 may be located in a differentlocation. For example, the controller 130 may be part of the transducerassembly 120 or the optical microphone assembly 125, or located externalto the eyewear device 100. Additional detail regarding the controller130 and the controller's 130 operation with other components of theaudio system can be found in the detailed description of FIGS. 3 & 4.

Audio System

FIG. 2A is a profile view 200 of a portion of an audio system includingan optical fiber microphone as a component of an eyewear device (e.g.,the eyewear device 100), in accordance with one or more embodiments. Inthis embodiment, the transducer assembly 120 includes a cartilageconduction transducer 220, an air conduction transducer 225, and a boneconduction transducer 230. The optical sensing pathway 235 is acomponent of the optical microphone assembly 125. The optical sensingpathway 235 detects audio pressure waves produced by one or more of thecartilage conduction transducer 220, the air conduction transducer 225,or the bone conduction transducer 230.

In the embodiment shown in FIG. 2A, the optical sensing pathway 235 isan optical fiber through which light travels to detect acoustic pressurenear the entrance to an ear 210 of the user. The light traveling throughthe optical fiber may be a sensing beam that is transmitted by a laserhoused in the frame 105. The sensing beam travels through the opticalfiber in a direction away from the frame 105. The sensing beam isreflected at the end of the optical fiber and travels back through theoptical fiber towards a detector, which is also be housed in the frame105. For example, the optical sensing pathway 235 may include aFabry-Perot interferometer at the end near the entrance to the ear 210.The Fabry-Perot interferometer includes a half mirror and a full mirrorpointed towards each other, so that the sensing beam passes back andforth between these two mirrors. The mirrors may be separated by air oranother medium. The acoustic pressure waves modulate the sensing beam asis passes between the two mirrors. In other embodiments, other types ofinterferometer configurations may be used. In some embodiments, lighttravels in a single direction through the optical fiber, and the opticalsensing pathway 235 includes both a forward and return pathway (i.e.,the optical sensing pathway 235 forms a loop). An acoustic pressure wavegenerated, either directly or indirectly, by one or more of thetransducers 220, 225, or 230 interacts with the sensing beam as thesensing beam travels through the optical fiber (e.g., within theFabry-Perot interferometer at the end of the optical fiber) such thatthe acoustic pressure wave alters an optical path length of the sensingbeam. The optical microphone assembly 125 determines the optical pathlength of the sensing beam that traveled through the optical fiber, andmeasures the acoustic pressure wave based on the detected optical pathlength of the sensing beam. The components of the optical microphoneassembly 125 are described in greater detail with respect to FIG. 4.

As depicted in FIG. 2A, the optical sensing pathway 235 is an opticalfiber that is suspended from the frame 105, which is a housing of theaudio system. In this case, the optical sensing pathway 235 extendsdirectly from the frame 105 towards the entrance of the ear 210. Theoptical sensing pathway 235 measures airborne acoustic waves produced bythe transducers 220, 225, or 230. For example, the optical sensingpathway 235 measures an airborne pressure wave directly produced by theair conduction transducer 225 and conducted through the air in thevicinity of the ear 210. The optical sensing pathway 235 measures anairborne pressure wave indirectly produced by the cartilage conductiontransducer 220 or the bone conduction transducer 230, i.e., an airbornepressure wave that is produced from a tissue borne pressure wave. Thelength of the optical fiber may be either longer or shorter than it isdepicted in FIG. 2A. A longer optical fiber may increase sensitivity ofthe optical microphone, while a shorter optical fiber may be lessdistracting to a user. In some embodiments, the optical sensing pathway235 includes a rigid component extending from the frame 105 and aflexible optical fiber extending from the rigid component and positionednear the entrance of the ear 210. In an embodiment, the optical sensingpathway 235 suspended from the housing of the audio system is configuredto be coupled to tissue of the user.

The cartilage conduction transducer 220 is coupled to a portion of theback of an auricle of an ear 210 of a user. The cartilage conductiontransducer 220 vibrates the back of auricle of the ear 210 of a user atfirst range of frequencies to generate a first range of airborneacoustic pressure waves at an entrance of the ear 210 based on audioinstructions (e.g., from the controller). The air conduction transducer225 is a speaker (e.g., a voice coil transducer) that vibrates over asecond range of frequencies to generate a second range of airborneacoustic pressure waves at the entrance of the ear. The first and secondranges of frequencies may be different or may have some overlap. Thefirst range of airborne acoustic pressure waves and the second range ofairborne acoustic pressure waves travel from the entrance of the ear 210down an ear canal 215 where an eardrum is located. The eardrum vibratesdue to fluctuations of the airborne acoustic pressure waves which arethen detected as sound by a cochlea of the user (not shown in FIG. 2).The optical sensing pathway 235 and other components of the opticalmicrophone assembly 125 are positioned at the entrance of the ear 210 ofthe user to detect the acoustic pressure waves produced by the cartilageconduction transducer 220 and the air conduction transducer 225.

The bone conduction transducer 230 is coupled to a portion of the user'sbone behind the user's ear 210. The bone conduction transducer 230vibrates over a third range of frequencies. The bone conductiontransducer 230 vibrates the portion of the bone to which it is coupled.The portion of the bone conducts the vibrations to create a third rangeof tissue borne acoustic pressure waves at the cochlea which is thenperceived by the user as sound. The vibration within the inner earcreated by the bone conduction transducer 230 results in a weak airborneacoustic pressure wave outside the user's ear. The optical sensingpathway 235 and other components of the optical microphone assembly 125are configured to detect the airborne acoustic pressure waves producedby the bone conduction transducer 230.

More particularly, the bone conduction transducer 230 generates tissueborne pressure waves that travel through the user's bone (e.g., themastoid) to the inner ear, which contains the cochlea. When the tissueborne pressure waves reach the inner ear, the waves within the inner earvibrate the ear drum from the inside, which generates weak airbornepressure waves on the outside of the user's ear drum. For example, theairborne pressure waves outside the user's ear may result in particledisplacements on the order of nanometers or picometers. These airbornepressure waves are too weak to be detected by typical binauralmicrophones or microphone arrays. However, the optical sensing pathway235 is sensitive enough to detect particle displacements on the order ofnanometers or picometers, and therefore can detect acoustic pressurewaves generated by the bone conduction transducer 230.

Although the portion of the audio system, as shown in FIG. 2A,illustrates one cartilage conduction transducer 220, one air conductiontransducer 225, one bone conduction transducer 230, and one opticalsensing pathway 235 configured to produce and detect audio content forone ear 210 of the user, other embodiments include an identical setup toproduce audio content for the other ear of the user. Other embodimentsof the audio system comprise any combination of one or more cartilageconduction transducers, one or more air conduction transducers, and oneor more bone conduction transducers. Examples of the audio systeminclude a combination of cartilage conduction and bone conduction,another combination of air conduction and bone conduction, anothercombination of air conduction and cartilage conduction, etc.

FIG. 2B is a profile view 250 of a portion of an audio system includingan optical microphone with a flexible membrane as a component of aneyewear device (e.g., the eyewear device 100), in accordance with one ormore embodiments. The transducer assembly 120 includes a cartilageconduction transducer 270, an air conduction transducer 275, and a boneconduction transducer 280, which are similar to the cartilage conductiontransducer 220, air conduction transducer 225, and bone conductiontransducer 230 described with respect to FIG. 2A. The optical sensingpathway 285 is a component of an alternative embodiment of the opticalmicrophone assembly 125. The optical sensing pathway 285 detectsairborne audio pressure waves produced by one or more of the cartilageconduction transducer 270, the air conduction transducer 275, or thebone conduction transducer 280.

In the embodiment shown in FIG. 2B, the optical sensing pathway 285 isan optical fiber 295 to which a membrane 290 is coupled. The membrane290 is flexible, and the optical fiber 295 is attached to the membrane290 in such a way that when the membrane 290 moves (e.g., in response toan acoustic pressure wave), the length of the optical sensing pathway285 changes. The optical fiber 295 may be rigid, so that the changes inoptical path length are generated by movement of the membrane 290,rather than movement of the optical fiber 295. The membrane 290 andoptical fiber 295 are connected to the frame 105 and positioned in thevicinity of the ear canal 265. As with the optical fiber in FIG. 2A, asensing beam emitted by a laser housed in the frame 105 travels into andthrough the optical fiber 295. The sensing beam is reflected by themembrane 290 and travels back through the optical fiber 295 towards adetector. The sensing beam output by the optical fiber 295 is directedtowards the detector.

An acoustic pressure wave generated by one or more of the transducers270, 275, or 280 interacts with the sensing beam as the sensing beamtravels through the optical fiber such that the acoustic pressure wavealters an optical path length of the sensing beam. In particular, themembrane 290 moves with the detected acoustic pressure wave, and themovement of the membrane 290 causes a change in the optical path lengthof the optical fiber 295. For example, when the acoustic pressure wavepushes the membrane 290 in the direction of the frame 105, this shortensthe optical path length compared to a neutral position of the membraneposition 290. The optical microphone assembly 125 determines the opticalpath length of the sensing beam that traveled through the optical fiber295, and measures the acoustic pressure wave based on the detectedoptical path length of the sensing beam. For example, the membrane 290may vibrate with an acoustic pressure wave, and a detected amplitude ofthe vibrations, as measured by an amount of variation of the opticalpath length, may be correlated to an amplitude of the detected acousticpressure wave. The coupled optical fiber 295 is sensitive to acousticpressure waves on the order of nanometers or even picometers, allowingthe detection at low volumes and detection of pressure waves generatedby the bone conduction transducer 280.

While in FIG. 2B the membrane 290 of the optical sensing pathway 285 ispositioned near the entrance to the ear 260, in other embodiments, theoptical sensing pathway 285 and/or membrane 290 is located at adifferent position. For example, the optical fiber 295 and attachedmembrane 290 may be mounted directly on the frame 105, rather than theoptical fiber 295 extending from the frame 105 towards the entrance ofthe user's ear as shown in FIG. 2B. In other embodiments, the membrane290 and coupled optical fiber 295 are coupled to tissue of a user'shead. For example, the membrane 290 is coupled to the auricle of the ear260 or to a bone in the user's head. Coupling the membrane 290 to a bonein the user's head may further improve detection of acoustic pressurewaves generated by the bone conduction transducer 280. In this example,the membrane 290 measures a tissue borne pressure wave, rather than anairborne pressure wave resulting from a tissue borne pressure wave. Insome embodiments, the audio system includes multiple optical sensingpathways, e.g., one optical sensing pathway near the ear canal fordetecting airborne acoustic pressure waves, and a second optical sensingpathways coupled to tissue for detecting tissue borne acoustic pressurewaves.

As shown in FIG. 2B, the optical sensing pathway 285 has an opticalfiber 295 that is suspended from the housing of the audio system (e.g.,the frame 105). In one embodiment, the optical sensing pathway 285(e.g., the membrane 290) is configured to be coupled to tissue of theuser. In another embodiment, an end of the optical sensing pathway 285(e.g., the membrane 290) is configured to be suspended in air andpositioned at an entrance to the ear of the user (e.g., the entrance tothe ear canal 265, as shown in FIG. 2B).

FIG. 3 is a block diagram of an audio system 300, in accordance with oneor more embodiments. The audio system in FIG. 1 is an embodiment of theaudio system 300. The audio system 300 includes one or more transducers310, an acoustic assembly 320, and a controller 330. In one embodiment,the audio system 300 further comprises an input interface. In otherembodiments, the audio system 300 can have any combination of thecomponents listed with any additional components. Similarly, thefunctions can be distributed among the components in a different mannerthan is described here.

The transducers 310 comprise any combination of one or more cartilageconduction transducers, one or more air conduction transducers, and oneor more bone conduction transducers, in accordance with one or moreembodiments. The transducers 310 provide sound to a user over a totalrange of frequencies. For example, the total range of frequencies is 20Hz-20 kHz, generally around the average range of human hearing. Each ofthe transducers 310 is configured to vibrate over various ranges offrequencies. In one embodiment, each of the transducers 310 operatesover the total range of frequencies. In other embodiments, eachtransducer operates over a subrange of the total range of frequencies.In one embodiment, one or more transducers operate over a first subrangeand one or more transducers operate over a second subrange. For example,a first transducer is configured to operate over a low subrange (e.g.,20 Hz-500 Hz) while a second transducer is configured to operate over amedium subrange (e.g., 500 Hz-8 kHz) and a third transducer isconfigured to operate over a high subrange (e.g., 8 kHz-20 kHz). Inanother embodiment, subranges for the transducers 310 partially overlapwith one or more other subranges.

In some embodiments, the transducers 310 include a cartilage conductiontransducer. A cartilage conduction transducer is configured to vibrate acartilage of a user's ear in accordance with audio instructions (e.g.,received from the controller 330). The cartilage conduction transduceris coupled to a portion of a back of an auricle of an ear of a user. Thecartilage conduction transducer includes at least one transducer tovibrate the auricle over a first frequency range to cause the auricle tocreate an acoustic pressure wave in accordance with the audioinstructions. Over the first frequency range, the cartilage conductiontransducer can vary amplitude of vibration to affect amplitude ofacoustic pressure waves produced. For example, the cartilage conductiontransducer is configured to vibrate the auricle over a first frequencysubrange of 500 Hz-8 kHz. In one embodiment, the cartilage conductiontransducer maintains good surface contact with the back of the user'sear and maintains a steady amount of application force (e.g., 1 Newton)to the user's ear. Good surface contact provides maximal translation ofvibrations from the transducers to the user's cartilage.

In one embodiment, a transducer is a single piezoelectric transducer. Apiezoelectric transducer can generate frequencies up to 20 kHz using arange of voltages around +/−100V. The range of voltages may includelower voltages as well (e.g., +/−10V). The piezoelectric transducer maybe a stacked piezoelectric actuator. The stacked piezoelectric actuatorincludes multiple piezoelectric elements that are stacked (e.g.mechanically connected in series). The stacked piezoelectric actuatormay have a lower range of voltages because the movement of a stackedpiezoelectric actuator can be a product of the movement of a singlepiezoelectric element with the number of elements in the stack. Apiezoelectric transducer is made of a piezoelectric material that cangenerate a strain (e.g., deformation in the material) in the presence ofan electric field. The piezoelectric material may be a polymer (e.g.,polyvinyl chloride (PVC), polyvinylidene fluoroide (PVDF)), apolymer-based composite, ceramic, or crystal (e.g., quartz (silicondioxide or SiO₂), lead zirconate-titanate (PZT)). By applying anelectric field or a voltage across a polymer which is a polarizedmaterial, the polymer changes in polarization and may compress or expanddepending on the polarity and magnitude of the applied electric field.The piezoelectric transducer may be coupled to a material (e.g.,silicone) that attaches well to an ear of a user.

In another embodiment, a transducer is a moving coil transducer. Atypical moving coil transducer includes a coil of wire and a permanentmagnet to produce a permanent magnetic field. Applying a current to thewire while it is placed in the permanent magnetic field produces a forceon the coil based on the amplitude and the polarity of the current thatcan move the coil towards or away from the permanent magnet. The movingcoil transducer may be made of a more rigid material. The moving coiltransducer may also be coupled to a material (e.g., silicone) thatattaches well to an ear of a user.

In some embodiments, the transducers 310 include an air conductiontransducer. An air conduction transducer is configured to vibrate togenerate acoustic pressure waves at an entrance of the user's ear inaccordance with audio instructions (e.g., received from the controller330). The air conduction transducer is in front of an entrance of theuser's ear. Optimally, the air conduction transducer is unobstructed,being able to generate acoustic pressure waves directly at the entranceof the ear. The air conduction transducer includes at least onetransducer (substantially similar to the transducer described inconjunction with the cartilage conduction transducer) to vibrate over asecond frequency range to create an acoustic pressure wave in accordancewith the audio instructions. Over the second frequency range, the airconduction transducer can vary amplitude of vibration to affectamplitude of acoustic pressure waves produced. For example, the airconduction transducer is configured to vibrate over a second frequencysubrange of 8 kHz-20 kHz (or a higher frequency that is hearable byhumans).

In some embodiments, the transducers 310 include a bone conductiontransducer. A bone conduction transducer is configured to vibrate theuser's bone to be detected directly by the cochlea in accordance withaudio instructions (e.g., received from the controller 330). The boneconduction transducer may be coupled to a portion of the user's bone. Inone implementation, the bone conduction transducer is coupled to theuser's skull behind the user's ear. In another implementation, the boneconduction transducer is coupled to the user's jaw. The bone conductiontransducer includes at least one transducer (substantially similar tothe transducer described in conjunction with the cartilage conductiontransducer) to vibrate over a third frequency range in accordance withthe audio instructions. Over the third frequency range, the boneconduction transducer can vary amplitude of vibration. For example, thebone conduction transducer assembly is configured to vibrate over athird frequency subrange of 100 Hz (or a lower frequency that ishearable by humans)-500 Hz.

The microphone assembly 320 detects acoustic pressure waves at theentrance of the user's ear. The microphone assembly 320 is an opticalmicrophone that includes an optical sensing pathway, such as one of theoptical sensing pathways described with respect to FIGS. 2A and 2B. Oneor more optical microphones may be positioned at an entrance of each earof a user. The microphone assembly 320 is configured to detect theairborne acoustic pressure waves formed at an entrance of the user'sears. Alternatively or additionally, the microphone assembly 320 isconfigured to detect the airborne acoustic pressure waves formed at anentrance of the user's ears. In one embodiment, the microphone assembly320 provides information regarding the produced sound to the controller330. The microphone assembly 320 transmits feedback information of thedetected acoustic pressure waves to the controller 330. An example ofthe microphone assembly 320 is described in greater detail with respectto FIG. 4.

The controller 330 controls components of the audio system 300. Thecontroller 330 generates audio instructions to instruct the transducers310 how to produce vibrations based on feedback from the microphoneassembly 320. For example, audio instructions may include a contentsignal (e.g., signal applied to any one of the transducers 310 toproduce a vibration), a control signal to enable or disable any of thetransducers 310, and a gain signal to scale the content signal (e.g.,increase or decrease amplitude of vibrations produced by any of thetransducers 310). For example, the controller 330 subdivides the audioinstructions into different sets of audio instructions for differenttransducers 310. A set of audio instructions controls a specifictransducer. In some embodiments, the controller 330 subdivides the audioinstructions for each transducer based on a frequency range for eachtransducer, based on a received selection of an audio source option fromthe user (e.g., via an input interface), or based on both the frequencyrange of each transducer and the received selection of an audio sourceoption.

For example, the audio system 300 may comprise a cartilage conductiontransducer, an air conduction transducer, and a bone conductiontransducer. Following this example, the controller 330 may designate afirst set of audio instructions for dictating vibration over a mediumrange of frequencies for the cartilage conduction transducer, a secondset of audio instructions for dictating vibration over a high range offrequencies for the air conduction transducer, and a third set of audioinstructions for dictating vibration over a low range of frequencies forthe bone conduction transducer. In additional embodiments, the sets ofaudio instructions instruct the transducers 310 such that a frequencyrange of one transducer partially overlaps a frequency range of anothertransducer.

The controller 330 generates the content signal of the audioinstructions based on portions of audio content and a frequency responsemodel. The audio content to be provided may include sounds over theentire range of human hearing. The controller 330 takes the audiocontent and determines portions of the audio content to be provided byeach of the transducers 310. In one embodiment, the controller 330determines portions of the audio content for each transducer based onthe operable frequency range of that transducer. For example, thecontroller 330 determines a portion of the audio content within a rangeof 100 Hz-300 Hz which may be the range of operation for a boneconduction transducer. The content signal may comprise a target waveformfor vibrating of each of the transducers 310. A frequency response modeldescribes the response of audio system 300 to inputs at certainfrequencies and may indicate how an output is shifted in amplitude andphase based on the input. With the frequency response model, thecontroller 330 may adjust the content signal so as to account for theshifted output. Thus, the controller 330 may generate a content signalof the audio instructions with the audio content (e.g., target output)and the frequency response model (e.g., relationship of the input to theoutput). In one embodiment, the controller 330 may generate the contentsignal of the audio instructions by applying an inverse of the frequencyresponse to the audio content.

The controller 330 receives feedback from the microphone assembly 320.The microphone assembly 320 provides information about the detectedacoustic pressure waves produced by one or more of the transducers 310.The controller 330 may compare the detected acoustic pressure waves witha target waveform based on audio content to be provided to the user. Thecontroller 330 can then compute an inverse function to apply to thedetected acoustic pressure waves such that the detected acousticpressure waves match the target waveform. Thus, the controller 330 canupdate the frequency response model of the audio system using thecomputed inverse function specific to each user. The adjustment of thefrequency model may be performed while the user is listening to audiocontent. The adjustment of the frequency model may also be conductedduring a calibration of the audio system 300 for a user. The controller330 can then generate updated audio instructions using the adjustedfrequency response model. By updating audio instructions based onfeedback from the microphone assembly 320, the controller 330 can betterprovide a similar audio experience across different users of the audiosystem 300.

In some embodiments of the audio system 300 with any combination of acartilage conduction transducer, an air conduction transducer, and abone conduction transducer, the controller 330 updates the audioinstructions so as to affect varying changes of operation to each of thetransducers 310. As each auricle of a user is different (e.g., shape andsize), the frequency response model will vary from user to user. Byadjusting the frequency response model for each user based on audiofeedback captured by the microphone assembly 320, the audio system canmaintain the same type of produced sound (e.g., neutral listening)regardless of the user. Neutral listening is having similar listeningexperience across different users. In other words, the listeningexperience is impartial or neutral to the user (e.g., does not changefrom user to user).

In another embodiment, the audio system uses a flat spectrum broadbandsignal to generate the adjusted frequency response model. For example,the controller 330 provides audio instructions to the transducers 310based on a flat spectrum broadband signal. The microphone assembly 320detects acoustic pressure waves at the entrance of user's ear. Thecontroller 330 compares the detected acoustic pressure waves with thetarget waveform based on the flat spectrum broadband signal and adjuststhe frequency model of the audio system accordingly. In this embodiment,the flat spectrum broadband signal may be used while performingcalibration of the audio system for a particular user. Thus, the audiosystem may perform an initial calibration for a user instead ofcontinuously monitoring the audio system. In this embodiment, themicrophone assembly 320 may be temporarily coupled to the audio system300 for calibration of the user. For example, after calibration, theoptical sensing pathway 235 or 285 can be removed from the eyeweardevice to improve comfort to the user.

In some embodiments, the controller 330 manages calibration of the audiosystem 300. The controller 330 generates calibration instructions foreach of the transducers 310. Calibration instructions may instruct oneor more transducers to generate an acoustic pressure wave thatcorresponds to a target waveform. In some embodiments, the acousticpressure wave may correspond to, e.g., a tone or a set of tones. Inother embodiments, the acoustic pressure wave may correspond to audiocontent (e.g., music) that is being presented to the user. Thecontroller 330 may send the calibration instructions to the transducers310 one at a time or multiple at a time. As a transducer receives thecalibration content, the transducer generates acoustic pressure waves inaccordance with the calibration instructions. The microphone assembly320 detects the acoustic pressure waves and sends the detected acousticpressure waves to the controller 330. The controller 330 compares thedetected acoustic pressure waves to the target waveform. The controller330 can then modify the calibration instructions such that thetransducers 310 emit an acoustic pressure wave that is closer to thetarget waveform. The controller 330 can repeat this process in until thedifference between the target waveform and the detected acousticpressure waves is within some threshold value. In one embodiment whereeach transducer is calibrated individually, the controller 330 comparesthe calibration content sent to the transducer against the detectedacoustic pressure waves by the microphone assembly 320. The controller330 may generate a frequency response model based on the calibration forthat transducer assembly. Responsive to completing calibration of theuser, the microphone assembly 320 may be uncoupled from the audio system300. Advantages of removing the microphone assembly 320 include makingthe audio system 300 easier to wear, reducing volume and weight of theaudio system 300 and potentially an eyewear device (e.g., eyewear device100, eyewear device 200, or eyewear device 250) of which the audiosystem 300 is a component, and reducing power consumption of the audiosystem 300.

FIG. 4 is a block diagram of a microphone assembly 320 of the audiosystem, in accordance with one or more embodiments. The microphoneassembly 320 shown in FIG. 4 is an optical Mach-Zehnder interferometerthat includes a laser 410 for generating a beam of light, a beamsplitter 420 for splitting the beam into a reference beam and a sensingbeam, an optical sensor 430 through which the sensing beam passes, areference beam modulator 440 through which the reference beam passes,and a detector assembly 450 for measuring the sensed acoustic pressurewave based on the sensing beam and the reference beam.

The laser 410 emits a beam of light. The laser 410 may be any coherentlight source, such as a laser diode. The laser 410 is coupled into abeam splitter 420. The beam splitter 420 is a device configured toseparate the light beam emitted by the laser 410 into a first beam oflight and a second beam of light. For example, the beam splitter 420 maybe a half-silvered mirror, a pair of glass prisms, or a dichroicmirrored prism. The first beam is a sensing beam used to detect anacoustic pressure wave, and the second beam is a reference beam that isused to detect changes in the sensing beam.

The first beam (i.e., the sensing beam) is coupled into an opticalsensor 430. The optical sensor 430 includes an optical sensing pathwaythrough which the sensing beam travels. In some embodiments, the opticalsensing pathway is configured to move with a detected acoustic pressurewave so that the sensing beam can sense the acoustic pressure wave. Forexample, the optical sensor 430 may be an optical fiber with aFabry-Perot interferometer as described with respect to FIG. 2A, or anoptical fiber coupled to a flexible membrane, as described with respectto FIG. 2B.

A detected acoustic pressure wave interacts with the optical sensor 430to alter an optical path length of the sensing beam. Optical path lengthis the product of the geometric length of the path that the sensing beamtravels and the index of refraction of the material through which thesensing beam travels (e.g., the index of refraction of the opticalfiber, or the index of refraction of the cavity between the mirrors in aFabry-Perot interferometer). The detected acoustic pressure wave createsparticle displacements in a transmission medium through which theacoustic pressure wave travels. For an airborne wave detected by anoptical sensing pathway suspended in air and positioned at an entranceto the user's ear, such as the optical sensing pathways shown in FIGS.2A and 2B, the transmission medium is air. For a tissue borne pressurewave detected by an optical sensing pathway coupled to tissue of theuser's head (e.g., in the vicinity of the bone conduction transducershown in FIGS. 2A and 2B), the transmission medium is tissue, such asbone or cartilage. In either case, the particle displacements created bythe acoustic pressure wave vibrate the optical sensing pathway (e.g.,the membrane or the Fabry-Perot interferometer), and this vibrationalters the geometric path length of the sensing beam through the opticalsensing pathway, and thus alters the optical path length. Measuringchanges to the optical path length provides a measurement of theparticle displacements, which corresponds to a measurement of acousticpressure.

The second beam (i.e., the reference beam) is coupled to a referencebeam modulator 440. The microphone assembly 320 compares the sensingbeam to the reference beam to measure the change to the optical pathlength of the sensing beam caused by the acoustic pressure wave. Thereference beam modulator 440 modulates a parameter of the reference beamso that the detector assembly 450 can identify the reference beam basedon the modified parameter and distinguish the reference beam from thesensing beam. For example, the reference beam modulator 440 can modulatethe amplitude or frequency of the reference beam.

The modulated reference beam output by the reference beam modulator 440and the sensing beam output by the optical sensor 430 are coupled into adetector assembly 450. In some embodiments, the modulated reference beamand the sensing beam are recombined prior to entering the detectorassembly 450, as shown in FIG. 4. For example, the reference beam andthe sensing beam output by the reference beam modulator 440 and theoptical sensor 430, respectively, may enter a second beam splitter thatoutputs a combined reference beam and sensing beam. The change to theoptical path length is observed in a change in the phase of the sensingbeam after passing through the optical sensor 430. The change in phaseof the sensing beam can be determined by comparing the phase of thesensing beam to the phase of the reference beam.

In the example shown in FIG. 4, the detector assembly 450 includes aphotodetector 460 and a signal processor 470. The combined modulatedreference beam and the sensing beam are coupled into the photodetector460. The photodetector 460 is a device that receives light and convertsthe light into an electrical current. The combination of the referencebeam and sensing beam yields constructive interference, and the amountof light detected at the photodetector 460 is related to the relativephases of the reference beam and the sensing beam. The signal processor470 receives the current generated by the photodetector 460 and convertsthe current into a measurement of the detected acoustic pressure wave.In particular, the signal processor 470 determines changes in theoptical path length of the sensing beam relative to the reference beambased on the relative phases of the sensing beam and the reference beam,and determines a measurement of the acoustic pressure wave based on thechanges in optical path length. The signal processor 470 transmits themeasurement of the acoustic pressure wave to the controller 330, whichadjusts an audio instruction for one or more of the transducers 310based on the measurement, as discussed above.

The signal processor 470 may also distinguish between changes to opticalpath length caused by acoustic pressure waves and changes to opticalpath length due to other factors. For example, if the audio system 300is worn by a user in motion, motion of the user's head may cause changesto the optical path length, e.g., due to motion of the optical fiber. Asan example, the signal processor 470 processes the received signal toidentify frequencies of detected changes to optical path length, andselects portions of the signal in a range of frequencies thatcorresponds to acoustic pressure waves (e.g., 20 Hz-20 kHz). Changes tooptical path length caused by physical motion are typically lowerfrequency, so the signal processor 470 can remove the portion of thereceived signal caused by physical motion as noise. In some embodiments,the controller 330 instructs a transducer 310 to produce acousticpressure waves at a particular frequency, set of frequencies, or rangeof frequencies, and transmits this frequency information to the signalprocessor 470. In such embodiments, the signal processor 470 measuresthe portion of the received signal that matches the frequencies of theproduced acoustic pressure waves.

While FIG. 4 shows an optical microphone assembly 320 based on aMach-Zehnder interferometer, in other embodiments, alternate detectiondevices can be used. For example, the optical microphone assembly may bebased on a Michelson interferometer, a Fizeau interferometer, or anothertype of optical interferometer or optical detection apparatus.

FIG. 5 is a system environment 500 of an eyewear device including anaudio system, in accordance with one or more embodiments. The system 500may operate in an artificial reality environment, e.g., a virtualreality, an augmented reality, a mixed reality environment, or somecombination thereof. The system 500 shown by FIG. 5 comprises an eyeweardevice 505 and an input/output (I/O) interface 515 that is coupled to aconsole 510. The eyewear device 505 may be an embodiment of the eyeweardevice 100. While FIG. 5 shows an example system 500 including oneeyewear device 505 and one I/O interface 515, in other embodiments, anynumber of these components may be included in the system 500. Forexample, there may be multiple eyewear devices 505 each having anassociated I/O interface 515 with each eyewear device 505 and I/Ointerface 515 communicating with the console 510. In alternativeconfigurations, different and/or additional components may be includedin the system 500. Additionally, functionality described in conjunctionwith one or more of the components shown in FIG. 5 may be distributedamong the components in a different manner than described in conjunctionwith FIG. 5 in some embodiments. For example, some or all of thefunctionality of the console 510 is provided by the eyewear device 505.

The eyewear device 505 may be a HMD that presents content to a usercomprising augmented views of a physical, real-world environment withcomputer-generated elements (e.g., two dimensional (2D) or threedimensional (3D) images, 2D or 3D video, sound, etc.). In someembodiments, the presented content includes audio that is presented viaan audio system 300 that receives audio information from the eyeweardevice 505, the console 510, or both, and presents audio data based onthe audio information. In some embodiments, the eyewear device 505presents virtual content to the user that is based in part on a realenvironment surrounding the user. For example, virtual content may bepresented to a user of the eyewear device. The user physically may be ina room, and virtual walls and a virtual floor of the room are renderedas part of the virtual content.

The eyewear device 505 includes the audio system 300 of FIG. 3. Theaudio system 300 includes one or more sound conduction methods and anoptical microphone assembly for detecting the produced sound. Asmentioned above, the audio system 300 may include any combination of oneor more cartilage conduction transducers, one or more air conductiontransducers, and one or more bone conduction transducers. The audiosystem 300 provides audio content to the user of the eyewear device 505.The audio system 300 uses the optical microphone to monitor the producedsound so that it can compensate for a frequency response model for eachear of the user and can maintain consistency with produced sound acrossdifferent individuals using the eyewear device 505.

The eyewear device 505 may include a depth camera assembly (DCA) 520, anelectronic display 525, an optics block 530, one or more positionsensors 535, and an inertial measurement Unit (IMU) 540. The electronicdisplay 525 and the optics block 530 is one embodiment of a lens 110.The position sensors 535 and the IMU 540 is one embodiment of sensordevice 115. Some embodiments of the eyewear device 505 have differentcomponents than those described in conjunction with FIG. 5.Additionally, the functionality provided by various components describedin conjunction with FIG. 5 may be differently distributed among thecomponents of the eyewear device 505 in other embodiments, or becaptured in separate assemblies remote from the eyewear device 505.

The DCA 520 captures data describing depth information of a local areasurrounding some or all of the eyewear device 505. The DCA 520 mayinclude a light generator, an imaging device, and a DCA controller thatmay be coupled to both the light generator and the imaging device. Thelight generator illuminates a local area with illumination light, e.g.,in accordance with emission instructions generated by the DCAcontroller. The DCA controller is configured to control, based on theemission instructions, operation of certain components of the lightgenerator, e.g., to adjust an intensity and a pattern of theillumination light illuminating the local area. In some embodiments, theillumination light may include a structured light pattern, e.g., dotpattern, line pattern, etc. The imaging device captures one or moreimages of one or more objects in the local area illuminated with theillumination light. The DCA 520 can compute the depth information usingthe data captured by the imaging device or the DCA 520 can send thisinformation to another device such as the console 510 that can determinethe depth information using the data from the DCA 520.

The electronic display 525 displays 2D or 3D images to the user inaccordance with data received from the console 510. In variousembodiments, the electronic display 525 comprises a single electronicdisplay or multiple electronic displays (e.g., a display for each eye ofa user). Examples of the electronic display 525 include: a liquidcrystal display (LCD), an organic light emitting diode (OLED) display,an active-matrix organic light-emitting diode display (AMOLED), someother display, or some combination thereof. The electronic display 525may be a waveguide display.

In some embodiments, the optics block 530 magnifies image light receivedfrom the electronic display 525, corrects optical errors associated withthe image light, and presents the corrected image light to a user of theeyewear device 505. In various embodiments, the optics block 530includes one or more optical elements. Example optical elements includedin the optics block 530 include: a waveguide, an aperture, a Fresnellens, a convex lens, a concave lens, a filter, a reflecting surface, orany other suitable optical element that affects image light. Moreover,the optics block 530 may include combinations of different opticalelements. In some embodiments, one or more of the optical elements inthe optics block 530 may have one or more coatings, such as partiallyreflective or anti-reflective coatings.

Magnification and focusing of the image light by the optics block 530allows the electronic display 525 to be physically smaller, weigh less,and consume less power than larger displays. Additionally, magnificationmay increase the field of view of the content presented by theelectronic display 525. For example, the field of view of the displayedcontent is such that the displayed content is presented using almost all(e.g., approximately 110 degrees diagonal), and in some cases all, ofthe user's field of view. Additionally, in some embodiments, the amountof magnification may be adjusted by adding or removing optical elements.

In some embodiments, the optics block 530 may be designed to correct oneor more types of optical error. Examples of optical error include barrelor pincushion distortion, longitudinal chromatic aberrations, ortransverse chromatic aberrations. Other types of optical errors mayfurther include spherical aberrations, chromatic aberrations, or errorsdue to the lens field curvature, astigmatisms, or any other type ofoptical error. In some embodiments, content provided to the electronicdisplay 525 for display is pre-distorted, and the optics block 530corrects the distortion when it receives image light from the electronicdisplay 525 generated based on the content.

The IMU 540 is an electronic device that generates data indicating aposition of the eyewear device 505 based on measurement signals receivedfrom one or more of the position sensors 535. A position sensor 535generates one or more measurement signals in response to motion of theeyewear device 505. Examples of position sensors 535 include: one ormore accelerometers, one or more gyroscopes, one or more magnetometers,another suitable type of sensor that detects motion, a type of sensorused for error correction of the IMU 540, or some combination thereof.The position sensors 535 may be located external to the IMU 540,internal to the IMU 540, or some combination thereof.

Based on the one or more measurement signals from one or more positionsensors 535, the IMU 540 generates data indicating an estimated currentposition of the eyewear device 505 relative to an initial position ofthe eyewear device 505. For example, the position sensors 535 includemultiple accelerometers to measure translational motion (forward/back,up/down, left/right) and multiple gyroscopes to measure rotationalmotion (e.g., pitch, yaw, and roll). In some embodiments, the IMU 540rapidly samples the measurement signals and calculates the estimatedcurrent position of the eyewear device 505 from the sampled data. Forexample, the IMU 540 integrates the measurement signals received fromthe accelerometers over time to estimate a velocity vector andintegrates the velocity vector over time to determine an estimatedcurrent position of a reference point on the eyewear device 505.Alternatively, the IMU 540 provides the sampled measurement signals tothe console 510, which interprets the data to reduce error. Thereference point is a point that may be used to describe the position ofthe eyewear device 505. The reference point may generally be defined asa point in space or a position related to the eyewear device's 505orientation and position.

The I/O interface 515 is a device that allows a user to send actionrequests and receive responses from the console 510. An action requestis a request to perform a particular action. For example, an actionrequest may be an instruction to start or end capture of image or videodata, or an instruction to perform a particular action within anapplication. The I/O interface 515 may include one or more inputdevices. Example input devices include: a keyboard, a mouse, a gamecontroller, or any other suitable device for receiving action requestsand communicating the action requests to the console 510. An actionrequest received by the I/O interface 515 is communicated to the console510, which performs an action corresponding to the action request. Insome embodiments, the I/O interface 515 includes an IMU 540, as furtherdescribed above, that captures calibration data indicating an estimatedposition of the I/O interface 515 relative to an initial position of theI/O interface 515. In some embodiments, the I/O interface 515 mayprovide haptic feedback to the user in accordance with instructionsreceived from the console 510. For example, haptic feedback is providedwhen an action request is received, or the console 510 communicatesinstructions to the I/O interface 515 causing the I/O interface 515 togenerate haptic feedback when the console 510 performs an action.

The console 510 provides content to the eyewear device 505 forprocessing in accordance with information received from one or more of:the eyewear device 505 and the I/O interface 515. In the example shownin FIG. 5, the console 510 includes an application store 550, a trackingmodule 555 and an engine 545. Some embodiments of the console 510 havedifferent modules or components than those described in conjunction withFIG. 5. Similarly, the functions further described below may bedistributed among components of the console 510 in a different mannerthan described in conjunction with FIG. 5.

The application store 550 stores one or more applications for executionby the console 510. An application is a group of instructions, that whenexecuted by a processor, generates content for presentation to the user.Content generated by an application may be in response to inputsreceived from the user via movement of the eyewear device 505 or the I/Ointerface 515. Examples of applications include: gaming applications,conferencing applications, video playback applications, or othersuitable applications.

The tracking module 555 calibrates the system environment 500 using oneor more calibration parameters and may adjust one or more calibrationparameters to reduce error in determination of the position of theeyewear device 505 or of the I/O interface 515. Calibration performed bythe tracking module 555 also accounts for information received from theIMU 540 in the eyewear device 505 and/or an IMU 540 included in the I/Ointerface 515. Additionally, if tracking of the eyewear device 505 islost, the tracking module 555 may re-calibrate some or all of the systemenvironment 500.

The tracking module 555 tracks movements of the eyewear device 505 or ofthe I/O interface 515 using information from the one or more positionsensors 535, the IMU 540, the DCA 520, or some combination thereof. Forexample, the tracking module 555 determines a position of a referencepoint of the eyewear device 505 in a mapping of a local area based oninformation from the eyewear device 505. The tracking module 555 mayalso determine positions of the reference point of the eyewear device505 or a reference point of the I/O interface 515 using data indicatinga position of the eyewear device 505 from the IMU 540 or using dataindicating a position of the I/O interface 515 from an IMU 540 includedin the I/O interface 515, respectively. Additionally, in someembodiments, the tracking module 555 may use portions of data indicatinga position or the eyewear device 505 from the IMU 540 to predict afuture location of the eyewear device 505. The tracking module 555provides the estimated or predicted future position of the eyeweardevice 505 or the I/O interface 515 to the engine 545.

The engine 545 also executes applications within the system environment500 and receives position information, acceleration information,velocity information, predicted future positions, or some combinationthereof, of the eyewear device 505 from the tracking module 555. Basedon the received information, the engine 545 determines content toprovide to the eyewear device 505 for presentation to the user. Forexample, if the received information indicates that the user has lookedto the left, the engine 545 generates content for the eyewear device 505that mirrors the user's movement in a virtual environment or in anenvironment augmenting the local area with additional content.Additionally, the engine 545 performs an action within an applicationexecuting on the console 510 in response to an action request receivedfrom the I/O interface 515 and provides feedback to the user that theaction was performed. The provided feedback may be visual or audiblefeedback via the eyewear device 505 or haptic feedback via the I/Ointerface 515.

Additional Configuration Information

The foregoing description of the embodiments of the disclosure has beenpresented for the purpose of illustration; it is not intended to beexhaustive or to limit the disclosure to the precise forms disclosed.Persons skilled in the relevant art can appreciate that manymodifications and variations are possible in light of the abovedisclosure.

Some portions of this description describe the embodiments of thedisclosure in terms of algorithms and symbolic representations ofoperations on information. These algorithmic descriptions andrepresentations are commonly used by those skilled in the dataprocessing arts to convey the substance of their work effectively toothers skilled in the art. These operations, while describedfunctionally, computationally, or logically, are understood to beimplemented by computer programs or equivalent electrical circuits,microcode, or the like. Furthermore, it has also proven convenient attimes, to refer to these arrangements of operations as modules, withoutloss of generality. The described operations and their associatedmodules may be embodied in software, firmware, hardware, or anycombinations thereof.

Any of the steps, operations, or processes described herein may beperformed or implemented with one or more hardware or software modules,alone or in combination with other devices. In one embodiment, asoftware module is implemented with a computer program productcomprising a computer-readable medium containing computer program code,which can be executed by a computer processor for performing any or allof the steps, operations, or processes described.

Embodiments of the disclosure may also relate to an apparatus forperforming the operations herein. This apparatus may be speciallyconstructed for the required purposes, and/or it may comprise ageneral-purpose computing device selectively activated or reconfiguredby a computer program stored in the computer. Such a computer programmay be stored in a non-transitory, tangible computer readable storagemedium, or any type of media suitable for storing electronicinstructions, which may be coupled to a computer system bus.Furthermore, any computing systems referred to in the specification mayinclude a single processor or may be architectures employing multipleprocessor designs for increased computing capability.

Embodiments of the disclosure may also relate to a product that isproduced by a computing process described herein. Such a product maycomprise information resulting from a computing process, where theinformation is stored on a non-transitory, tangible computer readablestorage medium and may include any embodiment of a computer programproduct or other data combination described herein.

Finally, the language used in the specification has been principallyselected for readability and instructional purposes, and it may not havebeen selected to delineate or circumscribe the inventive subject matter.It is therefore intended that the scope of the disclosure be limited notby this detailed description, but rather by any claims that issue on anapplication based hereon. Accordingly, the disclosure of the embodimentsis intended to be illustrative, but not limiting, of the scope of thedisclosure, which is set forth in the following claims.

What is claimed is:
 1. A method comprising: separating light into a reference beam and a sensing beam, the sensing beam coupled to an optical fiber that is coupled to an eyewear device, the optical fiber moving due to an acoustic pressure wave and physical motion of the eyewear device, wherein an end of the optical fiber is suspended in the air such that the end is proximate to an entrance of an ear canal of a user and the movement of the optical fiber alters an optical path length of the sensing beam; detecting the reference beam and the sensing beam from the optical fiber, wherein the detecting is performed using a photodetector that generates an electrical signal responsive to the detecting; removing, by an electrical signal processor, a portion of the electrical signal corresponding to the physical motion of the eyewear device to form a remaining portion of the electrical signal; and measuring the acoustic pressure wave based in part on changes in the optical path length described by the remaining portion of the electrical signal.
 2. The method of claim 1, wherein a beam splitter separates the light into the reference beam and the sensing beam.
 3. The method of claim 1, further comprising: modulating a parameter of the reference beam; and identifying the reference beam based on the modulated parameter.
 4. The method of claim 1, wherein the optical fiber is suspended from a housing of an audio system.
 5. The method of claim 1, wherein a portion of the optical fiber is configured to be coupled to tissue of the user.
 6. The method of claim 1, the method further comprising: selecting a portion of the electrical signal that have frequencies within 20 Hz-20 kHz.
 7. An audio system comprising: a beam splitter configured to separate light into a reference beam and a sensing beam, the sensing beam coupled to an optical fiber that is coupled to an eyewear device, the optical fiber moving due to an acoustic pressure wave and physical motion of the eyewear device, wherein an end of the optical fiber is suspended in the air such that the end is proximate to an entrance of an ear canal of a user and the movement of the optical fiber alters an optical path length of the sensing beam; and a detector assembly configured to: detect using a photodetector the reference beam and the sensing beam from the optical fiber, wherein the photodetector is configured to generate an electrical signal responsive to detection of the reference beam and the sensing beam, remove, by an electrical signal processor, a portion of the electrical signal corresponding to the physical motion of the eyewear device to form a remaining portion of the electrical signal; and measure the acoustic pressure wave based in part on changes in the optical path length described by the remaining portion of the electrical signal.
 8. The audio system of claim 7, further comprising: a reference beam modulator configured to modulate a parameter of the reference beam, wherein the detector assembly is configured to identify the reference beam based on the modulated parameter.
 9. The audio system of claim 7, further comprising: a transducer assembly configured to be coupled to an ear of the user and to produce an acoustic pressure wave based on an audio instruction.
 10. The audio system of claim 9, wherein the detector assembly is further configured to: adjust the audio instruction based on the measurement of the acoustic pressure wave.
 11. The audio system of claim 7, wherein the optical fiber is suspended from a housing of the audio system.
 12. The audio system of claim 7, wherein a portion of the optical fiber is configured to be coupled to tissue of the user.
 13. The audio system of claim 7, further comprising: a transducer configured to be coupled to a back of an auricle of an ear of the user, wherein the transducer is configured to vibrate the auricle over a first frequency range to cause the auricle to produce the acoustic pressure wave based on the audio instruction, and wherein the acoustic pressure wave with which the optical fiber is configured to move is in the first frequency range.
 14. The audio system of claim 13, further comprising: a second transducer configured to vibrate over a second frequency range, wherein the second transducer produces a second acoustic pressure wave, and wherein the optical fiber is further configured to move with the second acoustic pressure wave in the second frequency range.
 15. An optical microphone comprising: an optical fiber that moves due to an acoustic pressure wave; a beam splitter configured to separate light into a reference beam and a sensing beam, the sensing beam coupled to the optical fiber that is coupled to an eyewear device, the optical fiber moving due to an acoustic pressure wave and physical motion of the eyewear device, wherein an end of the optical fiber is suspended in the air such that the end is proximate to an entrance of an ear canal of a user and the movement of the optical fiber alters an optical path length of the sensing beam; and a detector assembly configured to: detect using a photodetector the reference beam and the sensing beam from the optical fiber wherein the photodetector is configured to generate an electrical signal responsive to detection of the reference beam and the sensing beam, remove, by an electrical signal processor, a portion of the electrical signal corresponding to the physical motion of the eyewear device to form a remaining portion of the electrical signal; and measure the acoustic pressure wave based in part on changes in the optical path length described by the remaining portion of the electrical signal. 